砷酸根和硒酸根的毛细管电泳分离

在铬酸盐和硼酸盐溶液中,以十六烷基三甲基溴化铵(CTAB)为电渗流改性剂,通过添加有机添加剂甲醇,成功地分离了砷酸根、硒酸根及常见酸根离子。优化分离条件发现,采用210 nm直接检测砷酸根比在260 nm处间接检测其检出限更低,而且可以减少大量C l-的干扰。迁移时间重复性的相对标准偏差(RSD)不大于3.0%,当信噪比(S/N)为2时,在260 nm处,HAsO42-与SeO42-的检出限分别为0.019 mg/L和0.078mg/L;在210 nm处,HAsO42-检出限可达0.004 3 mg/L。加标回收率均在95%~108%之间,满足定量要求。但NO3-会干扰HAsO42-的定量分析。     

以吡啶离子液体作为流动相添加剂的液相色谱法分析三氟乙酸根与三氟甲磺酸根

发展了用吡啶离子液体作为流动相添加剂的反相液相色谱分离和间接紫外检测三氟乙酸根和三氟甲磺酸根的分析方法。研究了吡啶离子液体、咪唑离子液体、对氨基苯酚盐酸盐和氯化四丁基铵作为流动相添加剂对三氟乙酸根和三氟甲磺酸根的影响,考察了吡啶离子液体的浓度、有机溶剂和检测波长等因素,并讨论了离子液体的作用、保留规律和相关机理。吡啶离子液体在分离检测中起到离子对试剂和紫外吸收试剂的作用。采用反相C_(18)色谱柱,以甲醇-0.3 mmol/L溴化N-己基吡啶水溶液(体积比10∶90)为流动相,在柱温30℃,流速1.0 m L/min,紫外检测波长250 nm条件下,三氟乙酸根和三氟甲磺酸根在12 min内完全分离,检出限分别为0.09、0.18 mg/L。将此法应用于离子液体中三氟乙酸根和三氟甲磺酸根阴离子的测定,加标回收率为96.0%~101%。该方法简单、准确,具有实用价值。     

离子色谱法同时测定离子液体中六氟磷酸根及痕量杂阴离子

建立了一种同时测定离子液体中六氟磷酸根(PF~6)和痕量杂阴离子氟、氯、溴(F~,Cl~,Br~)的离子色谱方法(IC)。样品经溶解、稀释、过滤后用Dionex IonPac AS22分离柱(250 mm×4 mm)分离,淋洗液为碳酸盐-乙腈体系(体积比为70:30),流速1.0 mL/min,采用Dionex DS6电导检测器检测,外标法定量。F~,Cl~,Br~和PF~6的线性范围分别为0.5～50 μg/L、10～200 μg/L、10～200 μg/L和0.9～45 mg/L,线性相关系数分别为0.9999,0.9998,0.9999和0.9998,加标回收率为94.5%～100.5%,相对标准偏差为0.63%～1.03%,检出限(以信噪比为3计)分别为0.5 μg/L、2.0 μg/L、5.0 μg/L和0.9 mg/L。该方法用于离子液体中六氟磷酸根和痕量杂阴离子的同时测定,结果令人满意。     

离子色谱法测定高锰酸钾中以及高浓度硝酸根中的高氯酸根

地下水和地表水中的高氯酸根危害人体健康。由于环境水样中的高浓度硝酸根和高锰酸钾基体干扰高氯酸根的测定,本方法通过滴加一定量的过氧化氢以除去高锰酸根,然后对样品进行离心来消除干扰。运用Dionex IonPac AS11型阴离子分离柱,流动相为8mmol/LKOH溶液,大体积(200μL)进样,抑制性电导检测器来测定有高锰酸钾以及高浓度硝酸根干扰的水中痕量高氯酸根。本方法的线性范围0.5~20mg/L,检出限为5μg/L。     

同时多组分分析动力学比均定中变换计算法的原理及其应用于光度法测定面包和水样中碘酸根和溴酸根

应用动力学方法,在不经分离的条件下,采用比均定中变换,同时测定面包与水样中溴酸根与碘酸根的含量.溴酸根、碘酸根的质量浓度在0.1～3.5 mg·L-1范围呈线性,比均定中值MC(D)与浓度C的线性回归方程的相关系数均在0.990 0以上,检出限分别为0.01 mg·L-1与0.02 mg·L-1,相对标准偏差分别为2.84%与1.96%,其回收率在82.2%～100.2%之间.     

恒波长同步荧光猝灭法测定饮用水中微量溴酸根

在HCl介质中,Δλ=20nm,溴酸根对罗丹明123的恒波长同步荧光有猝灭作用,且猝灭程度与溴酸根的含量呈线性关系,据此建立了恒波长同步荧光猝灭测定饮用水中的微量测定溴酸根的新方法。该方法的线性范围为0～200μg/L,检出限为3.0ng/mL。该方法可用于化学试剂和各种饮用水中溴酸盐含量的测定。     

吖啶橙荧光猝灭法测定饮用水中痕量溴酸根

基于在盐酸介质中,一定量的溴化钾存在下,当溴酸根氧化吖啶橙时使其荧光猝灭,提出了荧光猝灭法测定饮用水中溴酸根的方法。在激发波长493 nm,发射波长528 nm条件下,体系的荧光强度降低值△F与溴酸根的质量浓度在10.0～560.0μg·L^-1范围内呈线性关系,方法检出限（3S/N）为3.03μg·L^-1。方法用于纯净水和桶装水中溴酸根的测定,回收率在94.0%～107%之间。     

离子液体的阴离子三氟乙酸根、硫氰酸根、四氟硼酸根和三氟甲磺酸根的离子对色谱-直接电导检测法分析

建立了同时测定离子液体的阴离子三氟乙酸根、硫氰酸根、四氟硼酸根和三氟甲磺酸根的反相离子对色谱-直接电导检测方法。采用Diamonsil C18分离柱,以离子对试剂-苹果酸-乙腈水溶液为流动相,从流动相组成和色谱柱温度两方面讨论并确定了优化的色谱条件,即以0.15 mmol/L氢氧化四丁铵-0.099 mmol/L苹果酸-20%(v/v)乙腈混合水溶液(pH 6.5)为流动相,柱温25 ℃。在此条件下,三氟乙酸根、硫氰酸根、四氟硼酸根和三氟甲磺酸根离子均达到基线分离,且不受其他常见阴离子氟离子、氯离子、溴离子、硝酸根、硫酸根的干扰。三氟乙酸根、硫氰酸根、四氟硼酸根和三氟甲磺酸根离子的检出限(信噪比为3)分别为0.21、0.07、0.36、0.12 mg/L。将方法应用于测定离子液体中三氟乙酸根、硫氰酸根、四氟硼酸根和三氟甲磺酸根离子,加标回收率为95.0%～104.6%。该法简便、快速、灵敏度较高,可满足离子液体样品的检测要求。     

固相萃取-离子色谱法测定地下水中痕量高氯酸根离子

建立了测定地下水中痕量高氯酸根（ClO~4）的固相萃取-离子色谱(SPE-IC)分析方法。0.7 L水样经预处理降低主要干扰离子Cl~、CO2~3和SO2~4的干扰后,使用Cleanert PWAX弱阴离子交换固相萃取小柱对地下水中痕量(μg/L级)的ClO~4进行富集,用6 mL 1%NaOH溶液洗脱,富集液经0.45 μm水膜过滤后,用IonPac AS20阴离子分离柱、50 μL进样环、40 mmol/L KOH溶液淋洗、抑制电导检测分离分析。结果表明,地下水样品中ClO~4的方法检出限和测定下限分别为0.15 μg/L和0.60 μg/L,进样质量浓度在1～15 μg/L范围内有很好的线性关系,线性相关系数为0.9992,回收率为99.7%～100.5%;该方法经济有效,可用于地下水中痕量ClO~4的检测。利用该方法测定了哈尔滨周边部分地区地下水中ClO~4浓度,检测结果与离子色谱-质谱联用法的检测结果的相对误差为1.85%～9.24%。     

方波伏安法测定食盐中的碘酸根离子

报道了一种测定碘酸根离子含量的方法。在 0 .5mol/L Na Cl介质中 ,碘酸根离子在汞膜电极上于 - 1 .2 5V( vs.Ag/Ag Cl)左右产生一灵敏的方波伏安峰 ,峰高与碘酸根离子浓度在一定范围内呈良好的线性关系 ,方法检出限为1 .0× 1 0 - 7mol/L,已用于加碘食盐中碘酸根含量的测定。     

Eliminating the chlorite interference in US Environmental Protection Agency Method 317.0 permits analysis of trace bromate levels in all drinking water matrices

A post-column reagent (PCR) method for bromate analysis in drinking water with a method detection limit (MDL) and method reporting limit (MRL) of 0.1 and 0.5 microg/l, respectively, has been developed by the United States Environmental Protection Agency (EPA) for future publication as EPA Method 317.0. The PCR method provides comparable results to the EPA's Selective Anion Concentration (SAC) method used to support the laboratory analysis of Information Collection Rule (ICR) low-level bromate samples and offers a simple, rugged, direct injection method with potential to be utilized as a compliance monitoring technique for all inorganic Disinfectants/Disinfection By-Products (D/DBPs). It has superior sensitivity for bromate compared to EPA Method 300.1, which was promulgated as the compliance monitoring method for bromate under Stage 1 of the D/DBP rule. This paper addresses elimination of the chlorite interference that was previously reported in finished waters from public water systems (PWSs) that employ chlorine dioxide as the disinfectant. An evaluation of Method 317.0 for the analysis of bromate in commercial bottled waters is also reported.     

Ion chromatographic determination of trace iodate, chlorite, chlorate, bromide, bromate and nitrite in drinking water using suppressed conductivity detection and visible detection

An ion chromatography method for the simultaneous determination of trace iodate, chlorite, chlorate, bromide, bromate and nitrite in drinking water has been developed using an anion-exchange column and the suppressed conductivity detector, followed by post-column addition of reagent to enhance visible absorbance detection of ions. A high capacity anion exchange Ion Pac9-HC column (250 mm x 4 mm I.D.) was used. Eight millimole per liter sodium carbonate was used as eluent, an auto-suppression external water mode was selected, 0.5 g/l o-dianisidine.2HCl (ODA)+4.5 g/l KBr+25% methanel+5.6% nitric acid was used as post-column reagent. The post-column reaction (PCR) temperature was at 60 degrees C, and the visible absorbance detected wavelength at 450 nm. The sample's pH and coexist anions had no influence on determination. The method enjoyed a wide linear range and a good linear correlation coefficient (r>0.999). The method detection limits were between 0.023 and 2.0 microg/l. The average recoveries ranged from 87.5 to 110.0%, and the relative standard deviations (RSD) were in the range of 1.1-4.6%. The analytical results by the method of post-column addition of reagent to enhance visible absorbance detection of anions was compared with that of the suppressed conductivity detection, and the former was proved to be better in sensitivity and selectivity. The results showed that this method was accurate, sensitive and might be good for application and suitable for trace analysis at the level of mug/l.     

Cyclodextrin-aided determination of iodate and bromate in drinking water by microcolumn ion chromatography with precolumn enrichment.

A selective and simple method for the determination of iodate (IO3-) and bromate (BrO3-) by microcolumn ion chromatography (IC) is presented. In this study, IO3- and BrO3- were determined as IBr2- and tribromide (Br3-), respectively, via a postcolumn reaction with bromide (Br) under acidic conditions with the aid of alpha-cyclodextrin (alpha-CD) in microcolumn IC. IO3- and BrO3- were selectively detected by the present method at a wavelength of 253 or 265 nm. The present system achieved good selectivity for IO3- and BrO3- as well as good repeatability under suitable conditions. Precolumn enrichment improved the detection limit, and allowed the determination of BrO3- in bottled water as low as sub microg L(-1) level in microcolumn IC.     

Determination of dissolved bromate in drinking water by ion chromatography and post column reaction: interlaboratory study

A collaborative study, International Evaluation Measurement Programme-25a, was conducted in accordance with international protocols to determine the performance characteristics of an analytical method for the determination of dissolved bromate in drinking water. The method should fulfill the analytical requirements of Council Directive 98/83/EC (referred to in this work as the Drinking Water Directive; DWD). The new draft standard method under investigation is based on ion chromatography followed by post-column reaction and UV detection. The collaborating laboratories used the Draft International Organization for Standardization (ISO)/Draft International Standard (DIS) 11206 document. The existing standard method (ISO 15061:2001) is based on ion chromatography using suppressed conductivity detection, in which a preconcentration step may be required for the determination of bromate concentrations as low as 3 to 5 microg/L. The new method includes a dilution step that reduces the matrix effects, thus allowing the determination of bromate concentrations down to 0.5 microg/L. Furthermore, the method aims to minimize any potential interference of chlorite ions. The collaborative study investigated different types of drinking water, such as soft, hard, and mineral water. Other types of water, such as raw water (untreated), swimming pool water, a blank (named river water), and a bromate standard solution, were included as test samples. All test matrixes except the swimming pool water were spiked with high-purity potassium bromate to obtain bromate concentrations ranging from 1.67 to 10.0 microg/L. Swimming pool water was not spiked, as this water was incurred with bromate. Test samples were dispatched to 17 laboratories from nine different countries. Sixteen participants reported results. The repeatability RSD (RSD(r)) ranged from 1.2 to 4.1%, while the reproducibility RSD (RSDR) ranged from 2.3 to 5.9%. These precision characteristics compare favorably with those of ISO 15601. A thorough comparison of the performance characteristics is presented in this report. All method performance characteristics obtained in the frame of this collaborative study indicate that the draft ISO/DIS 11206 standard method meets the requirements set down by the DWD. It can, therefore, be considered to fit its intended analytical purpose.     

Determination of trace concentrations of bromate in municipal and bottled drinking waters using a hydroxide-selective column with ion chromatography

The International Agency for Research on Cancer determined that bromate is a potential human carcinogen, even at low micro/l levels in drinking water. Bromate is commonly produced from the ozonation of source water containing naturally occurring bromide. Traditionally, trace concentrations of bromate and other oxyhalides in environmental waters have been determined by anion exchange chromatography with an IonPac AS9-HC column using a carbonate eluent and suppressed conductivity detection, as described in EPA Method 300.1 B. However, a hydroxide eluent has lower suppressed background conductivity and lower noise compared to a carbonate eluent and this can reduce the detection limit and practical quantitation limit for bromate. In this paper, we examine the effect of using an electrolytically generated hydroxide eluent combined with a novel hydroxide-selective anion exchange column for the determination of disinfection byproduct anions and bromide in municipal and bottled drinking water samples. EPA Methods 300.1 B and 317.0 were used as test criteria to evaluate the new anion exchange column. The combination of a hydroxide eluent with a high capacity hydroxide-selective column allowed sub-microg/l detection limits for chlorite, bromate, chlorate, and bromide with a practical quantitation limit of 1 microg/l bromate using suppressed conductivity detection and 0.5 microg/l using postcolumn addition of o-dianisidine followed by visible detection. The linearity, method detection limits, robustness, and accuracy of the methods for spiked municipal and bottled water samples will be discussed.     

Simultaneous determination of inorganic disinfection by-products and the seven standard anions by ion chromatography

For the first time, an ion chromatographic method for the simultaneous determination of the disinfection by-products bromate, chlorite, chlorate, and the so-called seven standard anions, fluoride, chloride, nitrite, sulfate, bromide, nitrate and orthophosphate is presented. The separation of the ten anions was carried out using a laboratory-made high-capacity anion-exchanger. The high capacity anion-exchanger allowed the direct injection of large sample volumes without any sample pretreatment, even in the case of hard water samples. For quantification of fluoride, chloride, nitrite, sulfate, bromide, nitrate, orthophosphate and chlorate, a conductivity detection method was applied after chemical suppression. The post-column reaction, based on chlorpromazine, was optimized for the determination of chlorite and bromate. The method detection limit for bromate measured in deionized water is 100 ng/l and for chlorite, it is 700 ng/l. In hard drinking water, the method’s detection limits are 700 ng/l (bromate) and 3.5 μg/l (chlorite). The method’s detection limits for the other eight anions, determined by conductivity detection, are between 100 μg/l (nitrite) and 1.6 mg/l (chlorate).     

Spectrofluorimetric flow injection determination of trace amounts of periodate

A sensitive, rapid and selective procedure is proposed for the flow injection determinations of periodate by spectrofluorometric detection. The method is based on the reaction of periodate with Alizarin Navy Blue in basic solution. The reagents and manifold variables influence on the sensitivity have been investigated and the optimum conditions are established. Periodate can be determined for the range of 0.250-5.00 microg ml(-1) with a limit of detection of 0.08 microg ml(-1), and with a sample rate of 15 +/- 2 samples h(-1). The relative standard deviations for eight replicate determination of 0.500 and 5.00 microg ml(-1) was 1.3 and 1.1%, respectively. Periodate can be determined in the presence of iodate and bromate. The proposed method was used to determination of periodate in water samples.     

Sensitive kinetic-spectrophotometric determination of iodate in iodized table salt based on its accelerating effect on the reaction of bromate with chloride ion in the presence of hydrazine.

A simple, precise, sensitive and accurate method was developed for rapid determination of trace quantities of iodate. The method is based on the accelerating effect of iodate on the reaction of bromate and chloride acid in the presence of hydrazine in acidic media. The decolorization of Methyl Orange with the reaction products was used to monitor the reaction spectrophotometrically at 525 nm. Iodate could be determined in the concentration ranges of 0.03 - 1.2 microg ml(-1). The relative standard deviation for ten replicate determinations of 0.3 microg ml(-1) of iodate was 1.65%. The proposed method was applied to the determination of iodate in table salts with satisfactory results.     

Use of ion chromatography with post-column reaction for the measurement of tribromide to evaluate bromate levels in drinking water

A user-friendly ion chromatography method in conjunction with a post-column reaction (PCR) achieves practical quantitation limits for the oxyhalides bromate and chlorite of 0.05 μg/l and 0.10 μg/l, respectively. This level of measurement allows for the accurate assessment of bromate contributed to finished drinking waters that have been chlorinated using sodium hypochlorite. The target sensitivity of oxyhalides in the presence of other major ion species typically found in drinking water is achieved by PCR using excess bromide under acidic conditions to form a tribromide species that is detected by ultraviolet spectrometry. The method setup involves non-hazardous materials, as opposed to other recently developed methods that employ somewhat hazardous chemicals for generating the reaction necessary for the detection of bromate at sub-μg/l levels. No pretreatment of the samples is required, other than filtration and quenching of oxidant residual.     

离子色谱-柱后衍生紫外检测法测定化妆品中碘酸盐与溴酸盐

建立了同时检测化妆品中溴酸盐和碘酸盐的离子色谱-柱后衍生紫外检测器定量分析方法。样品用水提取,经RP柱净化,采用IonPac AS11-HC色谱柱分离,以EG40自动淋洗液发生器生成的KOH为淋洗液梯度洗脱,溴化钾、亚硝酸钠为衍生试剂,二极管阵列检测器检测,外标法定量。结果表明:该方法在2.0～1 000 mg/kg范围内线性关系良好(r≥0.999 8);加标回收率为84%～99%;相对标准偏差小于2%。方法简单、快速、选择性强,可用于化妆品中碘酸盐和溴酸盐的测定。